WO1984003794A1

WO1984003794A1 - Method for producing a composite insulator and insulator obtained thereby

Info

Publication number: WO1984003794A1
Application number: PCT/FR1984/000077
Authority: WO
Inventors: Alexandre Kaczerginski
Original assignee: Ceraver
Priority date: 1983-03-25
Filing date: 1984-03-23
Publication date: 1984-09-27
Also published as: ZA842214B; ES8501563A1; MX159090A; JPS60500929A; NO841131L; EP0120787A1; NO165017B; CA1238458A; EP0120787B1; JPH07118239B2; ES530936A0; ATE26502T1; FR2543356B1; AU2699284A; AU569882B2; US4702873A; BR8406458A; FR2543356A1; NO165017C; DE3463099D1

Abstract

Method for molding an insulating coating of an organic insulator comprising an elongate central rush (3) provided with end pins (5, 6). In the coating injection mold retractable supports (11, 12, 21, 22) are provided arranged at regular intervals; the injection is carried out and at the end of the injection, before the material is cured, the supports are retracted, the voids left by those supports in the mold (1, 2) being instantaneously filled by the injected material. Protection sleeves (24, 25) are interlayed between the rush and said supports.

Description

METHOD FOR MANUFACTURING A COMPOSITE INSULATOR AND INSULATOR OBTAINED

The present invention relates to a method of molding the insulating coating of a long organic organic insulator. Such an insulator comprises a central insulating element, such as a solid or hollow rod, the ends of which are provided with fittings.

The central rod is made of laminated material consisting of fibers coated with resin, and it is covered with an insulating coating in the form of a sheath generally provided with fins. The material of this coating is a hot vulcanizing elastomer of the EPM, EPDM type, silicone rubbers, polyurethanes or the like, optionally provided with mineral fillers (alumina, silica, etc.).

The invention relates in particular to insulators of length greater than 0.50 meters and up to two or three meters. If a rod of this length is placed in a mold and the elastomer is injected under a pressure of up to 500 bars, there is a deflection of the rod under the effect of the pressure of the material and different filling flows of the mold footprint. This results in significant variations in the thickness of the coating from one end to the other of the rod. To ensure a minimum thickness of the covering of the rod over the entire length of the rod, one solution would be to significantly increase the quantity of elastomer injected. However, this has disadvantages: increased weight of the insulator, vulcanization time and cost.

We therefore turned to another solution consisting in keeping the rod in place in the mold during the injection operation.

British Patent No. 599,570 discloses a method and a device for injection molding of an insulating coating on a metal insert in the form of a very thin pin. The coating material is thermoplastic, in other words it is heated to its softening or melting point and it is injected into a cold mold. A series of very thin rods are provided in the mold which hold the metal insert in place during the entire filling of the mold with the thermoplastic material and which are retracted automatically. when the mold is completely filled.

In the case of the organic insulator, the problem posed is much more complex. First, the rod has a modulus of elasticity four to five times lower than the aforementioned metal insert. It therefore tends to flex more than the metal insert. Furthermore, for the elastomer coating to have perfect adhesion to the surface of the rod, it is necessary to treat the rod prior to injection with adhesion agents, which is not the case with a metal insert. . In addition, the coating material vulcanizes hot, which implies that it is injected at an average temperature of around 100 ° C into a hot mold, the temperature of which is around 180 ° C to 200 ° C. .

If the provision of the abovementioned English patent were implemented, there would therefore be metal supports at the temperature of the mold which would come into contact with the adhesion agents on the surface of the rod and would immediately degrade them. This would cause adhesion defects of the coating on the rod, completely unacceptable in particular for medium and high voltage insulators. The object of the present invention is to avoid these drawbacks. The present invention relates to your method of molding the insulating coating of an organic electrical insulator comprising a central rod of composite material provided with surface adhesion agents, said insulating coating being made of a hot vulcanized elastomeric material, method according to which retractable supports are provided in the mold for said rod, characterized in that said rod is provided, at least at the level of the bearing surfaces against said supports, with protective sleeves whose thickness is less than that of said coating, that the material of said coating is then injected and that at the end of injection, before the vulcanization of said coating, said supports are retracted.

The material of the sleeves is advantageously made of elastomer, provided that it is compatible with the elastomer of the coating. The elastomer of the sleeves can be unvulcanized, or partially vulcanized, but for reasons of convenience of handling it is preferably vulcanized.

A sleeve may be formed by an elastomer ribbon wrapped around the ring, or by a split ring, or by a non-split ring expanded to be threaded on the ring and not to damage the adhesion agents, or by a ring molded in situ.

According to another embodiment, the different sleeves are joined together and define a continuous thin sheath. This sheath can be produced by known extrusion or in situ molding techniques; it can also be attached to the rod by interlacing.

According to another variant, said sleeves are metallic, for example made of aluminum alloy, cadmium-plated steel, galvanized steel; they are advantageously constituted by two half-rings crimped on the rod. It is also possible to produce these sleeves directly on the rod by vacuum spraying or electro-deposition of a metal compatible with these techniques (nickel, chrome, silver, copper for example).

All these variants make it possible to avoid any risk of deterioration of the sizing agents, and to obtain a coating of uniform thickness from one end to the other of the rod.

In order to further optimize the conditions aimed at obtaining this result, the positions of the injection channels are chosen with respect to those of the retractable supports to ensure a balanced distribution of said material around the rod. Thus, advantageously said injection channels are located substantially in the same transverse planes of the mold as the retractable supports. For example, an injection channel and a support are located in the extension of one another, on either side of the central rod.

According to another variant, an injection channel is orthogonal to two opposite supports located on either side of the central rod; it can also be on the bisector of the angle different from 180 ° C formed by the two supports.

It is also possible to provide separate transverse planes for the injection channels and the retractable supports. In this case the dimensions of the intervals between the supports will be determined so as to avoid any bending of the rod. Other characteristics and advantages of the invention will appear during the following description of different modes of implementation, given by way of illustration, but in no way limiting. In the attached drawing:

FIG. 1 very schematically shows in longitudinal section a mold allowing the method according to the invention to be implemented,

FIGS. 2 and 3 very schematically show in perspective two variants of protective sleeves for the rod appearing in FIG. 1,

- Figures 4 and 5 show in cross section an example of a mold at a retractable support, respectively before and after the end of the injection. We see in Figure 1 a mold in two parts 1 and 2 and its joint plane 4. A rod 3 provided with its fittings 5 and 6 is disposed in this mold. The imprint of the finned covering of the rod 3 has been referenced 7. Pairs of retractable supports 11, 12 and 21, 22 are regularly provided along the rod 3; they are associated with jacks 20 controlled automatically by the material injection machine, for example EPDM, intended to form the finned coating of the rod 3. The jacks 20 could also be controlled by means of '' a pressure sensor in contact with the material in the mold. The arrow 23 very schematically illustrates the introduction under pressure of the material into an injection channel towards the impression 7.

The rod 3 is provided with surface adhesion agents and has, at its bearing surfaces with the supports 11, 12, 21, 22, protective sleeves 24, 25 made of elastomer of formula compatible with the coating material with fins. Their thickness is less than the final thickness of this coating in the places where they are located.

Figures 2 and 3 show two examples of sleeves interposed between the support 12 and the rod 1. The sleeve 27 is obtained by spiraling an elastomer ribbon, while the sleeve 28 is formed by a split ring.

Any other embodiment can be envisaged, for example a closed ring, widely expanded before being threaded onto the rod so as not to damage the adhesion agents, then shrinking on the rod. The elastomer of these sleeves can be in the raw state or partially vulcanized, or in the vulcanized state; this latter state gives the sleeves a better mechanical strength allowing them in particular to better resist the stresses imparted to them by the injection flows. Whether vulcanized or not, these sleeves have active sites which subsequently make it possible to provide a completely satisfactory connection with the coating injected. According to another variant, the sleeves are molded in situ on the rod and are then in a vulcanized or semi-vulcanized state.

In all cases, when the end of injection is reached, the support pairs are retracted to the edges of the imprint 7, and complete this imprint. Thanks to the pressure exerted by the injected material, the spaces freed by the supports will be filled instantly, the coating is complete and vulcanization takes place. At the end of crosslinking, the sleeves adhere perfectly to the rod and the coating adheres perfectly to the rod and the sleeves.

It is easy to imagine that the sleeve appearing in FIG. 3 can be replaced by a metal sleeve; so as not to damage the adhesion agents of the rod, it is preferable to crimp two metal half-rings or to produce, before the application of these agents, sleeves by annular metal deposits.

In Figures 4 and 5 we see in cross section an embodiment for the retraction of the supports.

A rod 30 is placed in a two-part mold 31 and 32 whose joint plane is referenced 33. Supports 34, forming a cradle for the rod, are arranged regularly; the upper bearing face is separated from the surface of the rod by a sleeve 40; the inclined lower bearing face of each support 34 cooperates with a corner piece 35 capable of being driven in a translational movement (shown diagrammatically by the arrow 38 in FIG. 5).

In the figure plane is located an injection channel 36 for the flow 37, located substantially in the extension of the support 34. Such an arrangement allows the flow 37 to balance regularly around the rod.

We see in Figure 5 the retraction of the support 34, which becomes 34 'after translation of the corner 35, which becomes 35'.

According to a variant not illustrated, but which can easily be imagined from FIGS. 1 to 3, the various protective sleeves made of elastomer are connected together so as to form a unitary sheath. All that has been said above about the nature of the material of the sleeves, their state of vulcanization and their thickness is valid for the material of a continuous sheath. The latter however can be carried out directly on the rod by molding or by extrusion, or be attached to the rod. Of course, the invention is not limited to the embodiments which have just been described. In particular, it is not imperative that the injection channels are in the same transverse planes as the supports of the rod. But the distribution of the supports along the rod must always allow a balancing of the forces on the rod so that its bending is always less than the manufacturing tolerances.

The rod can be placed in the mold with its end fittings and a complete insulator is obtained immediately after molding. According to another variant, the end fittings are subsequently secured by any known means of sealing or sleeving.

Without departing from the scope of the invention, any means can be replaced by equivalent means. Thus the actual injection process of the material can be replaced by the known process called "compression-transfer" or "by transfer".

Claims

1 / A method of molding the insulating coating of an organic electrical insulator comprising a central rod made of composite material provided with surface adhesion agents, said insulating coating being made of a hot vulcanized elastomer material, method according to which provision is made in the mold retractable supports for said rod, characterized in that said rod is provided, at least at the level of the bearing surfaces against said supports with protective sleeves whose thickness is less than that of said coating, which is produced then the injection of the material of said coating and that at the end of injection, before the vulcanization of said coating, said supports are retracted.

2 / molding method according to claim 1, characterized in that the material of said coating and that of said sleeves are chosen from the group formed by hot vulcanizing elastomers such as EPM, EPDM, silicone rubbers, polyurethanes. 3 / molding method according to claim 2, characterized in that said sleeves are placed on the rod in the unvulcanized state. 4 / molding method according to one of claims 2 to 3, characterized in that, to produce said sleeves, elastomeric ribbons are spiraled around the rod.

5 / A molding method according to one of claims 2 to 3, characterized in that, to produce said sleeves, one uses split elastomer rings. 6 / molding method according to one of claims 2 to 3, characterized in that one puts on said sleeves on the rod by widening them beforehand.

7 / A molding method according to one of claims 2 to 3, characterized in that said sleeves are molded in situ on the rod. 8 / molding method according to one of claims 2 to 3, characterized in that said sleeves are joined so as to form a unitary sheath on the rod.

9 / A molding method according to claim 8, characterized in that said sheath is obtained by a method chosen from direct extrusion, direct molding, interlacing.

10 / A molding method according to claim 1, characterized in that the material is a metal. 11 / A molding method according to claim 10, characterized in that said sleeves are constituted by half-rings crimped on the rod.

12 / molding method according to claim 10, characterized in that, prior to the coating of the rod by the adhesion agents, said sleeves are produced by a process chosen from electro-deposition and vacuum metallization.

13 / Method according to one of the preceding claims, characterized in that the positions of the injection channels of the material of said coating are chosen vis-à-vis those of the retractable supports to ensure a balanced distribution of said material around said rod.

14 / A method according to claim 13, characterized in that there is provided injection channels located substantially in the same transverse planes of the mold as said retractable supports.

15 / A method according to claim 13, characterized in that there is provided an injection channel and a support located in the extension of one another on either side of said rod.

16 / A method according to claim 13, characterized in that there is provided an orthogonal injection channel with two opposite supports located on either side of said rod.

17 / Organic electrical insulator comprising a central rod whose ends are secured to two fittings and whose insulating coating is produced by the method according to one of the preceding claims.